Solution - Solving quadratic inequalities using the quadratic formula

The coefficients of our inequality, $$-1n^2+1n+3<0$$, are:

$$a$$ = -1

$$b$$ = 1

$$c$$ = 3

To find the roots of a quadratic equation, plug its coefficients ($$a$$, $$b$$ and $$c$$ ) into the quadratic formula:

$$n=\left(-b\pm sqrt\left(b^2-4ac\right)\right)/\left(2a\right)$$

$$n=\left(-1\pm sqrt\left(1^2-4*-1*3\right)\right)/\left(2*-1\right)$$

$$n=\left(-1\pm sqrt\left(1-4*-1*3\right)\right)/\left(2*-1\right)$$

$$n=\left(-1\pm sqrt\left(1--4*3\right)\right)/\left(2*-1\right)$$

$$n=\left(-1\pm sqrt\left(1--12\right)\right)/\left(2*-1\right)$$

$$n=\left(-1\pm sqrt\left(1+12\right)\right)/\left(2*-1\right)$$

$$n=\left(-1\pm sqrt\left(13\right)\right)/\left(2*-1\right)$$

$$n=\left(-1\pm sqrt\left(13\right)\right)/\left(-2\right)$$

to get the result:

$$n=\left(-1\pm sqrt\left(13\right)\right)/\left(-2\right)$$

Simplify $$13$$ by finding its prime factors:

The prime factorization of $$13$$ is $$13$$

$$n=\left(-1\pm sqrt\left(13\right)\right)/\left(-2\right)$$

The ± means two roots are possible.

Separate the equations:
$$n_1=\left(-1+sqrt\left(13\right)\right)/\left(-2\right)$$ and $$n_2=\left(-1-sqrt\left(13\right)\right)/\left(-2\right)$$

$$n_1=\left(-1+sqrt\left(13\right)\right)/\left(-2\right)$$

$$n_1=\left(-1+sqrt\left(13\right)\right)/\left(-2\right)$$

$$n_1=\left(-1+3.606\right)/\left(-2\right)$$

$$n_1=\left(-1+3.606\right)/\left(-2\right)$$

$$n_1=\left(2.606\right)/\left(-2\right)$$

$$n_1=\frac{2.606}{-}2$$

$$n_1=-1.303$$

$$n_2=\left(-1-sqrt\left(13\right)\right)/\left(-2\right)$$

$$n_2=\left(-1-3.606\right)/\left(-2\right)$$

$$n_2=\left(-1-3.606\right)/\left(-2\right)$$

$$n_2=\left(-4.606\right)/\left(-2\right)$$

$$n_2=-\frac{4.606}{-}2$$

$$n_2=2.303$$

To find the intervals of a quadratic inequality, we start by finding its parabola.

The roots of the parabola (where it meets the x-axis) are: -1.303, 2.303.

Since the $$a$$ coefficient is negative ($$a$$=-1), this is a "negative" quadratic inequality and the parabola points downward, like a frown.

If the inequality sign is ≤ or ≥ , then the intervals include the roots and we use a solid line. If the inequality sign is < or > the intervals do not include the roots and we use a dotted line.

Since $$-1n^2+1n+3<0$$ has a $$<$$ inequality sign, we look for the parabola intervals that are below the x-axis.

Solution: $$$$

Interval notation: $$$$